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Chemistry Extended Essay View metadata, citation and similar papersbrought atCORE core.ac.uk to you by provided by TED Ankara College IB Thesis ÖZTEKİN, Ali Barış 001129100 Chemistry Extended Essay “Investigation of the effect of magnetism on copper and iron electrolysis” Ali Barış ÖZTEKİN 001129100 Session: May 2012 Word Count:3954 Supervisor: Serenay Tarhan Güler TED Ankara Collage Foundation High School 1 ÖZTEKİN, Ali Barış 001129100 ABSTRACT Electrolysis has various real life applications in many different areas. It is used in the production many active metals, such as aluminum, and in automobile industry to fortify the metal used in the bodies of cars. Electrolysis is also important for space programs and military, where the electrolysis of water is used to produce necessary oxygen for the personnel in some vehicles such as spacecrafts and submarines. Since the rate of electrolysis is very important for these areas, a new method that increases the rate would benefit many areas that use the electrolysis in the process. This investigation is concerned with the effect of magnetism on the rate of electrolysis. For speeding up electrolysis for the areas mentioned earlier. The aim was to determine the effect of magnetic field with different magnitudes on the rate of electrolysis of copper and iron at a constant voltage, pressure with the same concentration of CuSO4 solution in 3 minutes. Two separate circuit systems were used, one being the electrolysis and other being the electromagnet. The experimentation process of the investigations consists of two parts. First experiment was carried out and the results showed an increase in the rate of electrolysis as the magnetic field increased. The second experiment was carried out to explain the gathered data in the first experiment in the light of Faraday’s Laws of Electrolysis, since the raw results from the first experiment needed to be expanded to be applicable to the Faraday’s Law. After the necessary calculations from the first experiment and data collection from the second experiment, the results were consistent with the Faraday’s Law. The final analysis showed that the increase in the strength of the magnetic field has increased the rate of electrolysis exponentially by changing the current of the electrolysis circuit. Word Count:296 2 ÖZTEKİN, Ali Barış 001129100 CONTENTS Abstract……………………………………………………………………………………… i Introduction…………………………………………………………………..………...…… 1 Electrolysis………………………..…………………………………….………...…. 2 Faraday’s Law of Electrolysis………………...……………………….………...…. 5 Magnetism.………………………..…………………………………….………...…. 6 Planning and Development…………………………………………….……………………6 Experiment 1……………………………………...…………………………..………...…… 7 Variables and Constants………….……………………………………………...…. 7 Data Collection of Experiment 1………………………..…………….…...…...…...9 Calculation of the Moles of Copper and Electrons ……………...……………… 10 Experiment 2……………………………………...………………………….………...……14 Data Collection of Experiment 2………………………..…………….…...…...…..13 Calculation of the current from the results of the Experiment 1………..…...…. 13 Results…………………………………...……………………………………….………….15 Conclusion……………………………..………………………………………………….... 17 Evaluation of the Experiments and Results……………………………..……………….. 18 Evaluation of the Materials and Method………………………………..……………….. 18 Further Investigation……………………………………………………..……………….. 19 Appendix 1…………………………………….…………………………..……………….. 20 Appendix 2…………………………………….…………………………..……………….. 24 3 ÖZTEKİN, Ali Barış 001129100 Appendix 3…………………………………….…………………………..……………….. 29 Bibliography…………………………………………………………….………………..…32 Pictures from the Experiment……..………………………………….………….……...…33 4 ÖZTEKİN, Ali Barış 001129100 INTRODUCTION The aim of this investigation is to identify a relation between the rate of electrolysis and the magnetic field. The chosen fields of study are Chemistry and Physics because the magnetic field and electrolysis are both concerned with the way charged particles’ move. The research question can be narrowed down to “What is the effect of magnetic field with different magnitudes on the rate of electrolysis of copper and iron at a constant voltage, pressure with the same concentration of CuSO4 solution in 3 minutes?” From the core subject High Level Chemistry and Physics in the IB curriculum it is taught that electrochemistry and magnetism play an important role in our lives even though we don’t notice them too much. The batteries that we use in daily life are based on redox reactions, which are an evolved version of an electrolytic cell. Also we use electrolysis in industrial process such as electroplating or electrolysis of water to obtain hydrogen and oxygen gases. In addition magnetism, also play an important role in our lives. From Magnetic Resonance Imaging in medicine to headphones magnetism has a great number of real-life applications. The reason of integration of Chemistry and Physics is that, although their fields of study are the study of matter in different aspects, as Physics is the study of matter and its motion and the Chemistry is the study of the matter in molecular level, they have common elements, such as particle physics and electrochemistry. The way atomic particles behave in particle physics for a certain physical situation is also valid for how particles behave in chemistry in the same circumstances therefore affecting the way the chemical reactions occur. The magnetic field accelerates charged particles by applying a force on them and since the electrolysis occurs by the movement of ions in a solution, the magnetic field should have an effect on the ions movement in electrolysis. (See Appendix 2 for detailed information.) If such an effect is discovered, the hypothesis is that the electrolysis process will be easier to carry out in industrial use, which will speed up the production of materials and benefiting the economy. The investigation of the effect of magnetism on electrolysis required an original experimental setup and procedure because of the fact that there weren’t any designated procedures for this kind of investigation. The electrolysis setup and an electromagnet were needed to be combined together in order to gather a proper set of data. 5 ÖZTEKİN, Ali Barış 001129100 This issue was resolved by placing the electromagnet below the electrolysis setup with the help of a tripod. The chosen place for electromagnet was below the electrolysis setup since the optimum effect of the magnetism could be evenly distributed.( See Figure 1) Electrolysis Atoms consist of electrically charged particle, which means that electricity has an important role in all the chemical reactions. Electricity is the name given for the flow of charged particles. The current is carried by electrons moves because of a source of potential difference in a circuit. In solutions of salts, the charge is carried in the circuit by the particles called ions. The substances that release ions when they are melted or dissolved in water are called electrolytes. The substances that are responsible for connecting the electrolytes to the current are called electrodes. There are two main electrochemical systems. The first one is called the electrolytic cell, which consists of two electrodes placed into an electrolyte solution and an outside source that provides potential difference is connected to the system. This kind of cells are capable of decompose elements from the solution, which is known as electrolysis and based on a non-spontaneous reaction. The other type of electrochemical cell is the voltaic cell. In this system, two electrodes made up of different metals are placed in an electrolytic solution, which provide a potential difference that creates a current in the system. This system is based on a spontaneous reaction to provide electricity. Both of these systems rely on oxidation-reduction (redox) reactions. In these systems the electrode in which oxidation occurs is called anode, and the electrode in which reduction occurs is called cathode. Electrolysis is a chemical process, which derives energy from an outside source of electrical energy to decompose molten salts or solutions to produce pure elements. Electrolysis requires two electrodes that are placed in a molten salt or a solution and any kind of direct current source. Similar to voltaic cells, the electrode where the reduction process occurs is referred as cathode. Other electrode where the oxidation process occurs is referred as anode. To this process to occur correctly, anode should be connected to the negatively charged side of the power source and the cathode should be connected to the positively charged side of the power supply. The negatively charged side repels the electrons and the positively charged side attracts electrons. This incident provides the circle that enables the 6 ÖZTEKİN, Ali Barış 001129100 electrons to transfer from one electrode to another. In other words electric current enables to drive a reaction, which is actually non-spontaneous in standard conditions. Picture 1: Electrolysis.1 Illustration of a simple electrolysis setup Electrolysis is a very important industrial process, which is used in the production process of active metals such as magnesium, sodium, and aluminum.2 There are some customized processes that enable to extract pure metals from rocks such as the Hall-Héroult Process for the production of aluminum.3 The process dissolves alumina in molten cryolite, which is a natural mineral containing alumina, and electrolyzing the molten salt bath to obtain pure aluminum metal. 1 http://www.ustudy.in/sites/default/files/electrolysis.jpg
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